Multiband superheterodyne radio receiver having a push-button station selector



March '21, 1950 H. M. EACH 2,501,591

IIULTIBAND SUPERl-iETERODYNE RADIO RECEIVER HAVING A PUSH BUTTON STATION SELECTOR 4 Sheets-Sheet 1 March 21, 1950 I H. M. BACH 2,501,591

MULTIBAND SUPERHETERODYNE RADIO RECEIVER HAVING A PUSH BUTTON STATION SELECTOR 4 Sheets-Sheet 2 Filed Aug. 27, 1945 n I W. W mxwwllllv l illi M 3 3 Q. s. n .RY lrl m u wn fiJ H. n 9; m UE I n M k\ EE Mm: u M@ HE III I.T. II II I March 21, 1950 H. M. BACH 2,501,591

MULTIBAND SUPERHETERODYNE RADIO RECEIVER HAVING A PUSH BUTTON STATION SELECTOR Filed Aug. 27, 1945 4 Sheets-Sheet 3 vz nrsn INJECTION GRID I: Q .U E l n 53;; m 2 9 L2 l L gwum'vf HENRY M. BAcH W/WKW March 21, 1950 H, c 2,501,591

MULTIBAND SUPERHETERODYNE RADIO RECEIVER HAVING A PUSH BUTTON STATION SELECTOR Filed Aug. 27, 1945 4 Sheets-Sheet 4 I. Swuamkon HENRY M- BACH MWWWK. M

Patented Mar. 21, 1950 MULT-IBAND SUPERHETERODYNE RADIO RECEIVER HAVING A PUSH-BUTTON STATIUN SELECTOR Henry M. liach vloodmereflN. Y., assignor'to Premier Crystal Laboratories, Incorporated,

'New York, N. Y.

Application August 27, 1945; SeriallNo. 612,931

8 Claims.

'1 This invention relates to radio receivingequipment, and more particularly to radio receiving equipment of the 'superheterodyne type.

A main object of the invention is to provide a novel and improved method and means of radio 5 reception wherein tuning isaccomplished by very simple manual operations and wherein extreme tuning accuracy; stability, and reliability of performance is obtained.

A further object of the invention is to provide an improved" method of radio receiver operation wherein tuning is accomplished of any desired signal frequency ina given band "of frequencies, such as the broadcast band or a shortwave band by the manipulation of a pair of selected push button elements, eachoneof said pair controlling the frequency-of a corresponding oscillator, and wherein the frequencies of the oscillators are mixed to provide an injection frequency, which when combined withthe signal frequency, provides a predeterminedintermediate frequency, the value of which is the same for any signal frequency in the band.

A still further objectof theinvention is to provide an improvedradio receivingstructure employing a plurality of crystal-controlled component oscillatorswhose frequencies are mixed to provideran injection frequency which is combined with a signalfrequency to provide a, predetermined intermediate frequency modulated by combined therewith to provide a predetermined intermediate frequency which is also of high stability .and which is. subsequently amplified and demodulated by the :receiver. structure.

Other objects and advantages of the invention will-become apparentfrom the following description and claims, and from theaccompanying drawings, wherein:

Figure 1, is a schematic block diagram illustrative of a-'-ra'dio receiving system constructed in accordance with and employing'the method of this invention.

Figure? is a diagra'mmatic view of 'a-push button panel "employed in the system of Figure 1 showingthe operative relationshipof the push button elements o'f saidpanel with circuit controlling "elements employedin said system.

Figure 3 isaschematic circuitdiagram-of an oscillator arrangement in accordance with this invention adapted to be employed in the radio receiving system of'Figure 1.

Figure 4 is a schematic block diagram illustrative of a modifiedradioreceiving system 'constructed in accordance with and employing the method of this'invention.

'-In the conventional superheterodyne radio receiver the oscillator is required to produce a frequency which, when mixed with the input signal frequency, produces the intermediate frequency. Ordinarily the oscillator is tuned by a first variable condenser which is ganged with another variable condenser-which controls the'tuning of the input stage of the receiver. The oscillator condenser must be-carefully. adjusted to track with the main tuning condenser to produce-a substantially constant intermediate frequency value for all 's'i'gnals'overthe tuning band, Perfect tracking .is practically :impossible to. obtain, so that ordinarily, compromise adjustments .are made whereby the condensers Jare trackedat 3 points over the tuning band.

Even if the condensers are initially adjusted for satisfactory tracking, they may be subsequently affected by conditions of temperature, vibration andzthelike, so as to become misali'gned and to thereby reduce the overall sensitivity of the 're'c'eiv'erieither at certain points in the'tuning band'ror' entirely: overrsaidband. This condition may be aggravated by 'further mechanical 'misalignment where push buttons -.:or other'mechanical devices are employed to establish the correct setting of the ganged tuning condensers, or, where no tunedinput stageis employed, merely by the thermal warping or axial shifting of the plates of the oscillator condenser.

.It is acom'mon fact, therefore, "that-after a 3 period of use, a superheterodyne receiver, manually operated either of the ganged condenser type or of the type employing push buttons, will lOse sensitivity and selectivity, and in a majority of cases the deterioration in performance can be traced to the misalignment of the oscillator condenser.

It is a prime purpose of this invention to provide a system of tuning for a superheterodyne receiver wherein no variable oscillator condenser is employed in tuning the receiver and wherein the initial conditions for producing the correct value of intermediate frequency at the input side of the intermediate frequency amplifier are permanently maintained for all channels of a tuning band.

In the broadcast band extending from 500 kc. to 1590 kc., all transmitting stations operate on multiples of 10 kc., such as 630 kc., 710 kc., 1500 kc., etc. In tuning the receiver over this band, it is therefore only necessary to tune to multiples of 10 kc. to receive any station in the band. In the range from 500 to 1590 kc. there are 110 channels respectively separated by 10 kc. Therefore in order to tune the receiver to any station in this band it must be :pOssible to set the oscillator or its equivalent to obtain a suitable value of frequency which will be variable at least in 10 kc. steps and which will combine with any signal frequency in the band to produce the intermediate frequency of the receiver.

It is also desirable to eliminate the possibilities of mistuning such as are inherent in the conventional condenser-tuned receiver employing either manual tuning or push-button mechanical tuning, such mistuning usually causing serious distortion. This problem has heretofore been dealt with by employing a crystal-controlled oscillator to beat with the signal frequency to produce the desired intermediate frequency value. As can be readily seen, however, 110 crystals would be required to operate the oscillator at all of the required frequencies for receiving all transmitting stations over the broadcast band, and appropriate switching means would have to be furnished for selectively connecting the crystals into the oscillator circuit. This would result in a very cumbersome arrangement.

In accordance with this invention, the number of crystals necessary to tune to all stations over a desired band is materially reduced by employing a plurality of crystal controlled oscillators in decade arrangement in :place of the single oscillator heretofore employed.

Referring to Figure 1, a receiver system in accordance with this invention is shown, said system comprising a heterodyne converter I I I which receives signal-modulated carrier energy from the antenna and an injection voltage from a mixing device I I2, said injection voltage being of proper frequency to combine with a predetermined signal carrier frequency to produce a fixed intermediate resultant frequency modulated by the signal. The intermediate frequency is amplified in the tuned amplifier II3 and is delivered to the detector I I4 for demodulation. The demodulated signal is then amplified in audio amplifier II5 and reproduced by a speaker device I It.

The mixing device H2 receives a first voltage from an oscillator I I! and a second voltage from an oscillator H8. The frequencies of oscillators III and H8 are selectively controlled by crystals. The frequency of oscillator II! is selectively controlled by a first variable crystal arrangement shown at I I9 and the frequency of oscillator I I8 is selectively controlled by a second variable crystal arrangement shown at I20. The control means for crystal arrangement H9 simultaneously controls the inductance of the variable secondary I2I of the input transformer for the converter III and the control means for crystal arrangement I20 simultaneously controls the capacitance of a variable capacitor arrangement I23 across the input conductors I53 and M4 of the converter III. For the broadcast band, secondary I2I is controlled to tune the converter input in kc. steps whereas capacitor arrangement I23 is controlled to tune the converter input in 10 kc. steps. As will subsequently be shown, crystal arrangement [I9 comprises a bank of eleven crystals adapted to be selectively connected by respective conductors I35 and I36 to oscillator III and crystal arrangement I20 comprises a bank of ten crystals adapted to be selectively connected by respective conductors I31 and I38 to oscillator H8. The frequencies of the crystals of crystal arrangement I I9 vary in 100 kc. steps and the frequencies of the crystals of crystal arrangement I20 vary in 10 kc. steps. The output of oscillator III may thus be regulated so as to vary in frequency in 100 kc. steps, and the output frequency of oscillator I I8 may be regulated so as to vary in 10 kc. steps. The outputs of the respective oscillators I II and I I8 are fed through appropriate low pass filters I24 and I25 into mixer H2 and are heterodyned. The resultant voltage is fed to converter I I I through an adjustable filter I26. The control means for filter I26 is ganged with a band switch I21 and the control means for said filter is arranged so that when the band switch is in broadcast position the filter I26 acts as a low pass filter. When the band switch I2? is set for short wave reception, filter I26 becomes a high pass filter. In the broadcast position of band switch I2! filter I26 passes the difference frequency of oscillators III and H8. In the short wave position of switch I2I filter I26 passes the sum frequency of oscillators I II and I I8.

In the arrangement shown in Figure 1, provision is made for one short wave band as well as a long wave band. In the position shown, band switch I21 engages a contact I39 which is connected by a conductor I40 to the untapped end of the winding of secondary I2I and thus is set for reception of the long wave band, as above described. In the second position of band switch I2'I converter I I I is connected by a switch contact MI and conductor I42 to the antenna through a broadly-tuned coil and condenser combination comprising a coil I28 connected in series with a condenser I29, these elements being adjusted so that condenser arrangement I23 will tune the input network to approximate resonance at the center of the'short wave band. The Q of the input network is made intentionally low so that excessive attenuation of the signals near the ends of the short wave band will not occur as a result of the input network being only approximately tuned to resonance. Otherwise the system functions substantially in the same manner as for the broadcast band, the sum frequencies of the oscillators III and II 8 being employed to vary the injection voltage frequency delivered to converter II I in 10 kc. steps over a range of 1090 kc. in the short wave region.

If extremely accurate tuning of the input circuit of converter III for the short wave band is desired, the same method of tuning may be employed as for the broadcast band.

Referring to Figure 2, a detailed arrangement quency by 100; kc., and: second; switches showntat B5,. 136,; etc., to B15, arranged. tux-selectively connect the return conductor I44 to suitably tapped poretions of the secondary I-2:I, thereby tuning the input: network of the converter. III in correspending-100 kc. steps;

The ten push. button. switches 300 150.390 're'-- spectively' control. first, switches shown at D,

Dm; etc., to Dan in the circuits for a second. bank.

of crystals indicated as V00, V10, etc., tO'Vsw, differing in frequency by kc., and second; switches shown. at E00, E10, etc: toEgo, arranged to selectively connect fixed condensers respectively indicated as C00, C10, etc., to C90, to theinput conductors I43. andv I 44 and having values selected to. tunev the input network of converter I II. in approximately IOIkc. steps overthe broadcast band; The bank of fixed condensers and their: switches correspond to variable condenser arrangement. I2 3 of Figure 1.

Crystals Xe to X and their switches correspond to variable crystal arrangement H9 and crystals V00 tovgo and their switches correspond to variable crystal arrangement I of Figure l.

A conventional mechanical arrangement is provided whereby any push-button in each row may be actuated to close its corresponding switch contacts, all other push-buttons of each row being released to maintain theirswitch contacts open. This enables any one of the crystals Xe to X15 to be connected to oscillator I I and any one of the crystals V00 to V90 to be connected to I oscillator H8 at av given time, the corresponding substantially exact antenna input circuit resonance conditions being simultaneously established for converter II I at least for the long wave band.

As stated above, crystalsrXs to X15 are separated in. frequency by; 100 kc; and crystals V00 to V790 are-separatedzin frequency by: 10 kc. The frequency ofoscillator -I:I.?I can. therefore be;var-

ied in 100 kc-..steps and. the frequency of oscil-=.

lator I-Bvcan be v varied in 10 kc. steps. This enables-.the-variation of thesresultant' injection frequency obtainedqfrom mixer H2 to be in l0kc. stepsover a first range extending from the differencebetween the frequency of the lowest crystal employed with oscillator I I1, say X5, and thehighest crystal employed with oscillator H8, say V00, to the difference between the highest crystal employed with oscillator III, say X15, and the lowest crystal employed with oscillator I I8, say V90.

The variation ofsaid injection frequency may also be in 10 kc. steps over a. second range extending from th frequency sum of the lowest crystal X5 employed with oscillator II! and the highest crystal V00 employed with oscillator H8, to the frequency sum of the highest crystal X15 employed with oscillator I I1 and the lowest crystal V90 employed with oscillator I I '8.

In a typical arrangement to cover the broad- 6 cast: band of frequencies extending. from. 500 kc. to. 1590 kcutilizing. the: diflerencefrequencies of oscillators IxI 'Iand; I:I8,..andi the short wave band.

of frequencies extending. from 9000 kc. to 10,090 kc., utilizing. the sum frequencies of. oscillators I I1 and I I 8 where an intermediate frequency ofv 455. kc. is employed, the following: crystal. frequencies;- are? employed:

7 Oscillator 1'17" Oscillator 118 Crystal Frequency Crystal Frequency ferencewirequenciesof oscillators II! and H8 as above described. Subtracting the broadcast band carrier frequency; the intermediate frequency of 455' kc: is obtained at" the" output of converter .I I l when th'e: appropriate push buttons are actuated.

Similarly-, utilizing th'ersumfrequencies of os- Provided-on panel I310" at one side, for example,

attthe-left' of eachof push-button switches 205 to 215, isa. translucent window carrying a number, thenumbers being from 5 consecutively to 15, cor-responding to 100 kc. intervals from 500 kc:.. to 1.500. kc. .Above thisrow of windows the panel-maycarryv identifying. indicia such as BC to indicate that this row of windows is for the broadcast band. -Similarly,translucent windows are provided at the left of push button. switches 300 t0 39.ll=, each. window carrying a number, the numbersbeing 00. to. .90 corresponding to 10. kc. intervals.

At the right .of pushbutton switches 205 to 2 I5 are translucent windows carrying numbers from 90. consecutively to 10.0 corresponding to 100 kc. intervalsfrom 9000' kc. to 10,000. kc., and at the right of push button switches-300 to 390'are translucent windows carrying numbers from to 00 corresponding to 10 kc. intervals using the sum frequencies of'the crystals. The right hand windows may carry identifying captions such as SW'to"in'dicate that these windows are for the shortwave band. 'Itwilfbe'noted that the num bering of the SW windows for push button switches 300 to 390 is in reverse order to the numbering for the BC windows. By consulting' theabove table 'it' can be seen that this reversal is necessary in order to properly select the frequency indicated by" the combination of numbers associated with the first row of push buttons and the second rowof push buttons. Thus, .towtune the SYStEm -WJO: a desired carrier frequency in the broadcast band, sa-y 6'30 kc;, thepush button 205, adjacent the window marked 6 and the push button 330, having the window marked 30 at its leftside, are depressed. This provides a crystal-controlled frequency of 5350 kc. for. oscillator II! and a" crystal controlled frequency of 4265 kc. for oscillator I I8. The difference frequency of 1085 kc. is derived in mixer H2 and is injected into converter III. This injection frequency beats with the 630 kc. carrier to provide a resultant intermediate frequency of 455 kc. which carries the signal modulations, as required by the receiver.

To tune the system to a desired carrier frequency in the short wave band, say 9550 kc., the

push button 2I0, adjacent the window marked 95, and the push button 340, adjacent the window at the right side thereof marked 50 are depressed. This provides a crystal-controlled frequency of 5750 kc. for oscillator II! and a crystal-controlled frequency of 4255 kc. for oscillator H8. The sum frequency of 10,005 kc. is derived in mixer H2 and is injected into converter III. This injection frequency beats with the 9550 carrier to provide a resultant intermediate frequency of 455 kc., which carries the signal modulations as required by the receiver.

Suitable lamps controlled by the actuating mechanism of band switch I21 may be provided behind the respective translucent windows to 11- luminate the BC windows when the band switch is set for broadcast reception and the SW windows when the band switch is set for short wave reception.

Figure 3 discloses, by way of example, a schematic circuit for oscillators I I1 and H8 and mixer II2. A twin triode I3I, which may be a type GSN"! tube, may be employed, with one section thereof employed for each oscillator. Variable crystal arrangement I I9, comprising the bank of crystals X to X shown in Figure 2, is connected by conductor I to the grid I of one section of twin triode I3I and variable crystal arrangement I20, comprising the bank of crystals V00 to Van shown in Figure 2, is connected by conductor I3! to the grid I40 of the other section of twin triode I3I. A low pass filter I24 is provided in the output circuit of oscillator III having a cut-off value of about 4500 kc. Low pass filter I24 is connected through a condenser I55 to a conductor I41 which is connected to an input grid I48 of a mixer tube I54. Another low pass filter I25 is provided. in the output circuit of oscillator I I8 having a cut-off value of about 6500 kc. Low pass filter I25 is, connected by a conductor I49 to a second input grid I50 of mixer tube I34. A third filter I25 is coupled to the plate I5I of tube I 34 and is in the output circuit of mixer II 2. Filter I25 is provided with movable switch members I32 and I33 mechanically connected to wave band switch 21 and having contacts I52, I53, I54 and I55 connected with the reactance elements L4 and C4 of filter I25 in such a manner that in the broadcast position of band switch I21 filter I26 constitutes a low pass filter having a cut-off value of about 2500 kc., whereas in the short wave position of band switch I21 filter I20 constitutes a high pass filter having a cut-off value of about 2500 kc. Filter I26 thus selective- 1y controls the passage of either the difference frequencies of oscillators I I! and H8 or the sum frequencies of said oscillators to the injectionv grid of converter III.

Mixer II2 may comprise a pentagrid tube I34 of the GSA? type as shown in Figure 3.

oscillators similar to the Pierce type.

Figure 4 shows in outline form the application of the tuning system of this invention to a receiver employing twoheterodyne stages. In the system of Figure 4 the signal input is heterodyned in the first converter stage 40I with a relatively high frequency crystal-controlled voltage produced by the first oscillator 402, resulting in a first intermediate frequency in the neighborhood of 4.3 megacycles. The first intermediate frequency amplifier 403 is arranged to have very low attenuation over a well defined band of frequencies ranging, say, from 4.26 to 4.35 megaband of frequencies.

rangement 404 comprising a bank of eleven crystals differing in frequency by kc. For tuning the system to the broadcast band of frequencies from 500 to 1590 kc. these crystals range from 4850 kc. to 5850 kc. For the band of frequencies from 500 to 590 kc.-, the first oscillator 402 is connected to the 4850 kc. crystal. A 500 kc. signal will beat with 4850 kc. to produce a 4.35 megacycle first intermediate frequency, whereas a 590 kc. signal will beat with 4850 kc. to produce a 4.26 megacycle first intermediate frequency. Therefore any signal between 500 kc. and 590 kc. will produce an intermediate frequency which will be passed by the first intermediate frequency ainplifier 403 when the 4850 kc. crystal is connected to the first oscillator. The following table indicates the respective 100 kc. bands tuned by the first oscillator crystalsz.

First Osc. Crystal Freq. Slgna] Kc. Kc.

4850 500 to 590 1950 600 to 690 5050 700 to 790 5150 800 50 890 5250 900 t!) 990 5350 1, C00 t0 1, 090 5450 1, 100 1 0 l, 190 5550 1, 200 l, 290 5650 1, 300 to 1, 391] 5750 1, 400 t0 1, 490 5850 1, 500 to 1, 590

The second oscillator 405 must provide a fre- Second Osc. Crystal Lastftg. o dilgits quency lgna Kc. Kc. 4, 085 90 4, 095 80- 4, 105 70 4,115 60 4,125 50 4,135 40 4,145 30 4,155 20 4, 10 4,17 00 It will readily be seen that tuning'is accomplished: in the same manner as in the embodiment of Figures 1 to 3..- Thus; to'tune to a630 kc; signal, the first oscillator-402th connected to the. 4950 kc. crystal. The first: oscillator frequencybeats with the 530 kc. signalto producea first intermediate-frequency of 4320:kc;. The 4145 kc. crystal is. connected to the second'zoscillator 40-5 in; accordance with the above table wherein-the 4145 kc. crystal appears oppsite30, representing the last two digits of the desired channel. The 4145 kc. second.- oscillator frequency beats with the first intermediatefrequency of 4320 to produce the: desired. 1'75 kc. second intermediate frequency voltage which carries the signal modulations.

The above described system of Figure 4 may also be employed to tune to any one of the 110 channels kc. apart extending from 9110 kc. to 10,200 kc. Thus, a 9110 kc. signal will beat with the 4850 kc. crystal frequency of the first oscillator 402 to produce an intermediate frequency of 4260 kc., and a 9200 kc. signal will beat with the 4850 kc. frequency to produce an intermediate frequency of 4350 kc. Similarly, a 10,110 kc. signal will beat with the 5850 kc. crystal frequency to produce the 4260 kc. intermediate frequency and a 10,200 kc. signal will beat with said 5850 kc. crystal frequency to produce the 4350 kc. intermediate frequency. By an appropriate adjustable low pass-high pass filter ahead of the first converter the system may be set for either broadcast or short wave reception. The push button panel, of course, should be provided with appropriate numerical markings adjacent the buttons for the first oscillator to indicate the respective hundreds of kc. for the broadcast band and for the short wave band, and the panel should be provided with appropriate markings adjacent the buttons for the respective tens of kc. for the broadcast band and the short wave band. The sequence of numerical markings for the tens buttons will be different for the short wave band than for the broadcast band.

Additional short wave channel ranges may be received by employing harmonic frequencies of the first crystal-controlled oscillator 402 which are available. For example, the second harmonics of the first oscillator will provide two additional bands, that is, employing the second harmonic of the first oscillator frequency plus or minus the first intermediate frequency, etc. When harmonics are thus employed, the push button tuning intervals are multiplied by an integer corresponding to the number of the harmonic.

While certain numerical values have been mentioned in connection with the method and elements of the specific embodiments of the invention described above, these values are merely illustrative of practical examples of the invention and are not to be construed as limiting. Other intermediate frequency values may be employed than those specified above, and of course, the crystal frequencies employed in the decade oscillators would be changed in accordance with the different intermediate frequency values employed. The new crystal frequencies could be readily calculated by one skilled in the art. I

While certain specific embodiments of a method and means for receiver tuning have been disclosed in the foregoing description, it will be understood that numerous modifications within the spirit of the invention may occur to those skilled in the art. Therefore it is intended that no limitations be-pIacedT-"on' the invention other than as quency of said second oscillator in predetermined finesteps, m'eans'for'combining the output voltages of said first and seco-ndoscillators to produce a resultant, and means for heterodyning said resultant with input radioffrequencyyenergy to-produce a predetermined intermediate frequency.

voltage.

2. The structure of claim 1, and wherein said coarse steps are steps of kc. and said fine steps are steps of 10 kc.

3. Tuning means for a radio receiver comprising an input device, an antenna coupled to said input device, a first crystal-controlled oscillator, means associated with said first crystal-controlled oscillator for generating predetermined crystal-controlled frequencies in 100 kc. steps, a second crystal-controlled oscillator, means associated with said second crystal-controlled oscillator for generating predetermined crystal-controlled frequencies in 10 kc. steps, means for mixing the frequencies of said first and second oscillators and combining a resultant frequency thereof with radio frequency input energy in said input device to thereby derive a predetermined intermediate frequency voltage.

4. The structure of claim 3, and wherein said mixing means includes a variable filter device mechanically linked to said input device for selecting either the difference frequencies or the sum frequencies of said first and second oscillators as said resultant frequency in accordance with the setting of said input device.

5. The structure of claim 3, and wherein said tuning means includes a first group of push buttons, each of which is adapted to select one of said 100 kc. step frequencies, and a second group of push buttons, each of which is adapted to select one of said 10 kc. step frequencies.

6. A radio receiver comprising an input device, an antenna coupled to said input device, means for tuning said input device, a first crystal-controlled oscillator, means associated with said first crystal-controlled oscillator for selectively generating a plurality of predetermined crystal-controlled frequencies in 100 kc. steps, a second crystal-controlled oscillator, means associated with said second crystal-controlled oscillator for selectively generating a plurality of crystal-controlled frequencies in 10 kc. steps, means for mixing the selected frequencies of said first and second oscillators and combining a resultant frequency thereof with tuned radio frequency energy in said input device to thereby derive a predetermined intermediate frequency voltage, and means for demodulating said intermediate frequency voltage.

'7. The structure of claim 6, and wherein said mixing means includes a variable filter device mechanically linked to said tuning means for selecting either the difference frequencies or the sum frequencies of said first and second oscillators as said resultant frequency in accordance with the setting of said tuning means for the input device.

8. The structure of claim 6, and wherein a first group of push button elements is provided, each push button element of said first group being adapted to select one of said 100 kc. step frequencies, and wherein a second group of push button elements is provided, each push button element of said second group being adapted to select one of said 10 kc. frequencies, the push button elements of at least one of said groups forming part of the tuning means for said input device.

HENRY M. BACH.

REFERENCES CITED The following references are of record in the file of this patent:

Number 12 UNITED STATES PATENTS Name Date De Kramolin Aug. '7, 1934 Terman Sept. 29, 1936 Siemens Mar. 28, 1939 Deerhake Jan. 14, 1941 Carlson June 10, 1941 Mayer July 13, 1943 Shaw July 18, 1944 Koch Aug. 21, 1945 FOREIGN PATENTS Country Date Number Germany Mar. 13, 1935 

